2,159 research outputs found
Are quantization rules for horizon areas universal?
Doubts have been expressed on the universality of holographic/string-inspired
quantization rules for the horizon areas of stationary black holes or the
products of their radii, already in simple 4-dimensional general relativity.
Realistic black holes are not stationary but time-dependent. Using two examples
of 4D general-relativistic spacetimes containing dynamical black holes for at
least part of the time, it is shown that the quantization rules (even counting
virtual horizons) cannot hold, except possibly at isolated instants of time,
and do not seem to be universal.Comment: One example and one figure added, two figures improved, bibliography
expanded and updated. Matches the version accepted for publication in Phys.
Rev.
Renormalizability of generalized quantum electrodynamics
In this work we present the study of the renormalizability of the Generalized
Quantum Electrodynamics (). We begin the article by reviewing the
on-shell renormalization scheme applied to . Thereafter, we calculate
the explicit expressions for all the counter-terms at one-loop approximation
and discuss the infrared behavior of the theory as well. Next, we explore some
properties of the effective coupling of the theory which would give an
indictment of the validity regime of theory: .
Afterwards, we make use of experimental data from the electron anomalous
magnetic moment to set possible values for the theory free parameter through
the one-loop contribution of Podolsky mass-dependent term to Pauli's form
factor .Comment: 9 page
Cluster Algorithm Renormalization Group Study of Universal Fluctuations in the 2D Ising Model
In this paper we propose a novel method to study critical systems numerically
by a combined collective-mode algorithm and Renormalization Group on the
lattice. This method is an improved version of MCRG in the sense that it has
all the advantages of cluster algorithms. As an application we considered the
2D Ising model and studied wether scale invariance or universality are possible
underlying mechanisms responsible for the approximate "universal fluctuations"
close to a so-called bulk temperature . "Universal fluctuations" was
first proposed in [1] and stated that the probability density function of a
global quantity for very dissimilar systems, like a confined turbulent flow and
a 2D magnetic system, properly normalized to the first two moments, becomes
similar to the "universal distribution", originally obtained for the
magnetization in the 2D XY model in the low temperature region. The results for
the critical exponents and the renormalization group flow of the probability
density function are very accurate and show no evidence to support that the
approximate common shape of the PDF should be related to both scale invariance
or universal behavior.Comment: 6 pages, 4 figures and 3 table
Relativistic free-particle quantization on the light-front: New aspects
We use the light-front machinery to study the behavior of a relativistic free
particle and obtain the quantum commutation relations from the classical
Poisson brackets. We argue that the usual projection onto the light-front
coordinates for these from the covariant commutation ralations does not
reproduce the expected results.Comment: To appear in the proceedings "IX Hadron Physics and VII Relativistic
Aspects of Nuclear Physics: A Joint Meeting on QCD and QGP, Hadron
Physics-RANP,2004,Angra dos Reis, Rio de Janeiro,Brazi
Surprises in the relativistic free-particle quantization on the light-front
We use the light front ``machinery'' to study the behavior of a relativistic
free particle and obtain the quantum commutation relations from the classical
Poisson brackets. We argue that their usual projection onto the light-front
coordinates from the covariant commutation relations show that there is an
inconsistency in the expected correlation between canonically conjugate
variables ``time'' and ``energy''. Moreover we show that this incompatibility
originates from the very definition of the Poisson brackets that is employed
and present a simple remedy to this problem and envisages a profound physical
implication on the whole process of quantization.Comment: 13 page
South-North trade, intellectual property jurisdictions, and freedom to operate in agricultural research on staple crops:
A biotechnology revolution is proceeding in tandem with international proliferation of intellectual property regimes and rights. Does the intellectual property impede agricultural research conducted in, or of consequence for, developing countries? This question has important spatial dimensions that link the location of production, the pattern of international trade, and the jurisdiction of intellectual property. Our main conclusion is that the current concerns about the freedom to operate in agricultural research oriented towards food crops for the developing world are exaggerated. Rights to intellectual property are confined to the jurisdictions where they are granted, and, presently, many of the intellectual property (IP) rights for biotechnologies potentially useful to developing-country agricultural producers are valid only in developed countries. IP problems might arise in technologies destined for crops grown in developing countries unencumbered by IP restrictions, if those crops are subsequently exported to countries in which IP is likely to prevail. Thus freedom to trade is also part of the IP story. However, using international production and trade data in the 15 crops critical to food security throughout the developing world, we show that exports from developing to developed countries are generally dwarfed by production and consumption in the developing world, the value of these exports is concentrated in a few crops and a few exporting countries, and the bulk of these exports go to Western Europe. Thus for now, most LDC researchers can focus primarily on domestic IPR in determining their freedom to operate with respect to food staples.Intellectual property., Biotechnology., Agricultural research., Trade regulation.,
Semiclassical theory for small displacements
Characteristic functions contain complete information about all the moments
of a classical distribution and the same holds for the Fourier transform of the
Wigner function: a quantum characteristic function, or the chord function.
However, knowledge of a finite number of moments does not allow for accurate
determination of the chord function. For pure states this provides the overlap
of the state with all its possible rigid translations (or displacements). We
here present a semiclassical approximation of the chord function for large
Bohr-quantized states, which is accurate right up to a caustic, beyond which
the chord function becomes evanescent. It is verified to pick out blind spots,
which are displacements for zero overlaps. These occur even for translations
within a Planck area of the origin. We derive a simple approximation for the
closest blind spots, depending on the Schroedinger covariance matrix, which is
verified for Bohr-quantized states.Comment: 16 pages, 4 figures
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